Vibrational Effects on the Acoustic Performance of Multi-Layered Micro-Perforated Metamaterials

IF 1.9 Q3 ENGINEERING, MECHANICAL
Vibration Pub Date : 2023-09-17 DOI:10.3390/vibration6030043
Cédric Maury, Teresa Bravo
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引用次数: 0

Abstract

Broadband noise reduction over the low–mid frequency range in the building and transportation sectors requires compact lightweight sound absorbers of a typical subwavelength size. The use of multi-layered, closely spaced (micro-)perforated membranes or panels, if suitably optimized, contributes to these objectives. However, their elasticity or modal behaviors often impede the final acoustical performance of the partition. The objective of this study is to obtain insights into the vibrational effects induced by elastic limp membranes or panel volumetric modes on the optimized sound absorption properties of acoustic fishnets and functionally graded partitions (FGP). The cost-efficient global optimization of the partitions’ frequency-averaged dissipation is achieved using the simulated annealing optimization method, while vibrational effects are included through an impedance translation method. A critical coupling analysis reveals how the membranes or panel vibrations redistribute the locations of the Hole-Cavity resonances, as well as their cross-coupling with the panels’ first volumetric mode. It is found that elastic limp micro-perforated membranes broaden the pass-band of acoustic fishnets, while smoothing out the dissipation ripples over the FGP optimization bandwidth. Moreover, the resonance frequency of the first panels mode sets an upper limit to the broadband optimization of FGPs, up to which a high dissipation, high absorption, and low transmission can be achieved.
振动对多层微穿孔超材料声学性能的影响
在建筑和交通领域中,中低频范围内的宽带降噪需要典型亚波长尺寸的紧凑轻质吸声器。多层、紧密间隔(微)穿孔膜或板的使用,如果适当优化,有助于实现这些目标。然而,它们的弹性或模态行为往往会阻碍隔板的最终声学性能。本研究的目的是深入了解弹性软膜或面板体积模式对声渔网和功能分级隔板(FGP)的最佳吸声性能的振动效应。采用模拟退火优化方法对隔板的频率平均耗散进行了经济高效的全局优化,同时采用阻抗平移法对振动效应进行了考虑。关键的耦合分析揭示了膜或面板振动如何重新分配孔腔共振的位置,以及它们与面板第一体积模式的交叉耦合。研究发现,弹性软质微孔膜拓宽了声渔网的通带,同时平滑了FGP优化带宽上的耗散波纹。此外,第一面板模式的共振频率对FGPs的宽带优化设置了上限,在此上限下可以实现高耗散、高吸收、低传输。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.20
自引率
0.00%
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审稿时长
10 weeks
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